Systems and Methods for Facilitation Communications Among Customer Relationship Management Users

ABSTRACT

A method for synchronizing Customer Relationship Management data between a Software as a Service (“SaaS”) CRM provider and a mobile device. This method enables both read and write access from the mobile device whether a network connection to the SaaS provider is available or not. The method involves creating a local mobile device database to track portions or all of the SaaS provider database. In the case where a network separation occurs and the device and SaaS databases diverge, the synchronization method may be used to make the mobile device database and the SaaS database consistent and coherent again. In one embodiment, multiple local database tables are used to represent a single SaaS CRM table to facilitate synchronization, and a status indicator is used to visually and quickly convey status to the mobile user.

APPLICATION PRIORITY DATA

This application is a Divisional Application of U.S. patent applicationSer. No. 13/898,628 entitled “SYSTEMS AND METHODS FOR FACILITATINGCOMMUNICATIONS AMONG CUSTOMER RELATIONSHIP MANAGEMENT USERS” byinventors Kraljevic, Vallabhaneni, and Rodriguez III, filed May 21,2013, which in turn claims the priority benefit of U.S. ProvisionalApplication No. 61/651,515 entitled “Systems and Methods forFacilitating Communications Among Sales Employees,” filed May 24, 2012.Both applications are incorporated herein by reference in theirentirety.

FIELD OF THE INVENTION

The present invention relates generally to the use of customerrelationship management systems, and more specifically, but not by wayof limitation, to systems and methods for facilitating communicationsamong customer relationship management users, and in some instances tothe bidirectional synchronization of customer relationship managementsystems and mobile devices.

BACKGROUND

Both mobile computing and software services in the cloud have becomevery popular in the past decade. Customer relationship managementsystems, such as the SalesForce software as service (“SaaS”), inparticular, have continued to grow in popularity, although asynchronous(e.g., offline) interactions between these systems and mobile deviceshave yet to be optimized.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a summary of various aspects of the present technology.

FIG. 2 illustrates bidirectional synchronization between a CRM systemand an application database that resides on a mobile device.

FIG. 3 illustrates various tables of an exemplary application database.

FIG. 4 illustrates various data flow diagrams for various actionsbetween the CRM system and the mobile device that are performed eitheronline or offline.

FIG. 5 illustrates an overview of an exemplary method forbidirectionally synchronizing a customer database and a local clientdatabase.

FIG. 6 illustrates a detailed view of the exemplary method of FIG. 5.

FIG. 7 illustrates an exemplary offline method for creating andutilizing a local client database.

FIG. 8 illustrates an exemplary offline method for updating objects on alocal client database.

FIG. 9 illustrates an exemplary offline method for deleting objects on alocal client database.

FIG. 10 illustrates an exemplary offline method for converting at leasta portion of a local client database.

FIG. 11 illustrates an exemplary querywave method.

FIG. 12 illustrates an exemplary online indicator and user interface foruse in accordance with the present technology.

FIG. 13 is a block diagram of an exemplary computing system forimplementing embodiments of the present technology.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

While this technology is susceptible of embodiment in many differentforms, there is shown in the drawings and will herein be described indetail several specific embodiments with the understanding that thepresent disclosure is to be considered as an exemplification of theprinciples of the technology and is not intended to limit the technologyto the embodiments illustrated.

It will be understood that like or analogous elements and/or components,referred to herein, may be identified throughout the drawings with likereference characters. It will be further understood that several of thefigures are merely schematic representations of the present technology.As such, some of the components may have been distorted from theiractual scale for pictorial clarity.

Referring now to the collective drawings, FIGS. 1-12, which depictvarious aspects of bidirectional synchronization between CRM systems andmobile devices. Generally described, the present technology allows aclient (e.g., mobile device) to interact with a customer relationshipmanagement system, such as the SalesForce SaaS to maintain a coherentdata copy that provides high availability to the user. The presenttechnology allows for application data synchronicity even in thepresence of network loss or failure, and syncs with the cloud mastercopy.

Application Database Organization

As background, a customer relationship management (“CRM”) system clouddeployment may consist of an RDBMS-like set of tables (otherwise knownas entities). Individual CRM systems may have a specific terminology forthis generic idea; for example, SalesForce terminology for a tablewithin the CRM platform is an SObject, hereinafter referred to as an“SObject” (singular) or “SObjects” (plural). A constituent part ofdesigning a client application that bidirectionally interacts (e.g.,synchronizes) with the CRM system involves establishing a scheme forrepresenting these SObjects locally in the client application, anddetermining how information between the cloud SObjects and the locallystored SObjects is kept coherent (e.g., synchronized or synced).Algorithms responsible for maintaining this coherence will be referredto as the Synchronization (or Sync) algorithm.

FIG. 2 illustrates an overall approach that may involve any of: (a)using a client local SQL database (such as SQLite) with a set of tablesto model each SObject (called an SObject Table group). The presenttechnology may also employ a set of shared singleton support tables andSQL transactions to safely support concurrent user accesses with thesynchronization algorithm, as well as a synchronization algorithm tomanage the data exchange between the client and server.

Note that in some instances not all server-side tables are necessarilycloned on the client. The Salesforce.com environment has dozens oftables, and a purpose-built client application is unlikely to requireall of them, although in some instances the present technology mayutilize all server-side tables of the CRM system.

Application Database Details

FIG. 3 includes a description and diagram of shared support tablesutilized by the present technology. The Property table contains a set ofkey/value pair properties. The Picklist table contains information fromthe SObject schema about multiple-choice picklist values for a field.The Createlist table (organized and utilized as a first in first out“FIFO”) contains a queue of entries representing local create orconvertLead operations. The entry with the lowest idx may be placed atthe head of the queue. Entries may be enqueued at the tail and dequeuedfrom the head. The FIFO nature of the Createlist is important becauseobjects in the list may refer to senior objects ahead in the list. Ifthey are not created on the cloud server (e.g., in the correct order,the server may reject the synchronization transaction.

Each Createlist row contains the following fields: (i) idx—queueordering index; (ii) IsCreate—“TRUE” if the entry represents a create;“FALSE” if the entry represents a convertLead. For the create case:(iii) TableName—Table that the entry was created in; (iv) TableId—ThetmpId assigned locally which needs to be replaced with a value assignedby the server.

For the convertLead case, the following fields correspond to thearguments to the Salesforce SOAP API convertLead( ) Note that theAccount, Contact, and Lead Id fields may be either real server-assignedvalues, or a tmpId locally-assigned value if there is a create operationcorresponding to that Id ahead of the convert in the Createlist. TheOpportunityId in the Createlist may be either a tmpId or empty (ifDoNotCreateOpportunity is “TRUE”). When created objects return from theserver, tmpId's may be swapped with real server Id's such that anysubsequent entries in the Createlist (as well as all other references inall other tables) may be corrected.

Additional SObjects include, but are not limited to, AccountId;ContactId; ConvertedStatus; DoNotCreateOpportunity; LeadId;OpportunityName; OverwriteLeadSource; Ownerld; andSendNotificationEmail.

OpportunityId—The tmpId may be assigned locally and may need to bereplaced with a value assigned by the server. The Deletelist containsthe set of entries that have been deleted locally. Note that theCreatelist and Deletelist may be empty at the end of a successfullycompleted sync.

Next we describe each of the tables in an SObject Table Group.<SObject>—The “main table” containing both locally changed and unchangeddata entries. Conceptually, this is convenient, because the applicationmay need only look at one table to get its latest data. Special fields(all boolean): CuriumCreated—This entry was locally create;CuriumUpdated—This entry was locally updated; CuriumConverted—(Leadonly) This entry was locally converted.

SObject>_todelete—A list of Ids of objects deleted by the server sincethe last sync. <SObject>_tosync—[Not typically needed]. A list of IDs ofextra objects to fetch from the server. <SObject>_synced—The actualmodified objects fetched from the server. <SObject>_orig—A backup of theoriginal unchanged object is made when an object is locally updated ordeleted. This is to assist future resolves (with the correspondingserver object) or undo the change.

The present technology may utilize the prefix “Curium” or any otherarbitrary prefix that does not conflict with naming conventions of theCRM system as a way of distinguishing local-only bookkeeping fields.

The main, _orig, and _synced tables for each SObject contain the entireset of fields that the cloud SObject table contains. Of these, the “Id”field is interesting because it may be used to uniquely identify objectinstances and correlate instances between the client and server.

Online vs. Offline Modes

The present technology may support both online and offline modes [seeFIG. 4]. Online mode is straightforward and the interaction betweenremote and local objects is depicted in FIG. 4. Note that for onlinecases, the remote object may be accessed first and the local object maybe updated to keep the local database as current as possible.

Also note that for the online update case, in order to reduce theprobability of a field client and server update collision, the objectvalue may be refreshed immediately upon entering the update flow. Thisensures the client has the most up to date copy of the server valuepossible before attempting the edit.

With regard to offline mode, accesses for the user may be satisfiedlocally, and writes (e.g., application data) may be stored locally andposted to the cloud server during a (future) synchronization pass.

The following description considers various techniques for implementinga state-of-the-art offline mode. A useful performance-enhancing hybridmode is an offline-read plus an online-write mode. This is equivalent tothe behavior of a write-through cache, where reads are satisfied locally(and are, hence, fast). Moreover writes of application data may godirectly to the server (specifically to the customer database of the CRMsystem) such that the server has the most up-to-date informationpossible and the client may not be required to carry un-synced changes.This mode works especially well when most accesses are reads and theuser is willing to manually initiate a sync when the most up-to-dateserver data is needed.

Sync Algorithm

FIG. 5 illustrates the operation of a synchronization algorithm that maybe responsible for maintaining coherence between the local and clouddatabases. The sync algorithm is made safely interruptible andre-startable by storing the current state and progress within that stateas properties in the property table.

A Sync process may begin by attempting at get a new Salesforce sessionIdif needed (loginIfSessionOld). This attempts to prevent failure of theSync operation due to an expired session.

The next stage reads the SObject schema. Schema information is stored tothe property table to permit offline access, as well as to enable changedetection for the cloud schema. In the event of a cloud schema change,the client must perform SQL commands to affect an equivalent changelocally to the main, _orig, and _synced tables in the SObject tablegroup. Schema for all SObjects may be queried in parallel. (SalesforceAPIs used: REST GET SObject describe.)

The initSObjects stage reads the saved schema information from theproperty table so the Sync algorithm has access to the field informationfor each SObject.

The syncWindowEndDate stage calculates the time window for performingthe main Sync, as well as a secondary time window for syncingserver-side deletes. Unfortunately, due to limitations in the SalesForcegetDeleted API, it may not be possible to maintain a single window. Thisstage uses the end date and time of the previously completed sync as thebeginning date and time for the current sync. The end time for thecurrent sync is determined by asking the SalesForce cloud server for itscurrent time. In order to keep things as consistent as possible, thesync algorithm uses the same start and end time for all SObjects.(Salesforce APIs used: SOAP getServerTime.).

The queryDeleted stage queries the server for any deleted object Ids fora given SObject within the calculated time range. Any IDs are stored inthe _todelete table. Server SObject tables can be queried in parallel,and having a per-SObject todelete table makes it easy to avoidcollisions when storing the results of the concurrent getDeleted()queries. (Salesforce APIs used: SOAP getDeleted.)

The queryModWave stage queries the cloud for records created or modifiedwithin the sync time window. SObject schema information is used to queryall fields of each SObject, or at least a portion thereof. SObjects maybe queried in parallel, and the results of the query are stored in the_synced table. The Query Wave concept is described in detail in a latersection, with reference to FIG. 11. As a special optimization, to givethe application a feeling of immediate usability the first ever time async is performed, the first ever sync may safely store results for thisstage directly into the main table since it's known that no resolve willneed to be performed. (Salesforce APIs used: REST SOQL query.)

The queryModBatch stage may not typically be used. If any data isspecifically desired to be fetched by the Bulk API, queries for thoserequests may be issued here. The fetchModified stage may also nottypically be used. If any rows in any of the _tofetch tables arepopulated, they are read here and stored in their corresponding _syncedtables. Generally, there is nothing to do here because the queryModWavestage may read all the created and modified objects itself, as will bedescribed in greater detail below.

Additionally, the fetchModBatch stage may not typically be used. If anybatch queries were issued in the queryModBatch stage, the results may beread back here and written to the appropriate _synced table depending onthe SObject.

The syncResolve stage walks through the full set of detailed resolvestages (see below). The syncFinish stage cleans up any final syncproperty values and returns the application to a state of sync not inprogress.

Resolve Stages

The resolveServerDeletes stage applies all server-initiated deletes byiterating through the entries in all _todelete tables. Any other tablerow with an Id value of the deleted object is also deleted.

The resolveLocalDeletes stage applies all locally-initiated deletes fromthe Deletelist table. In the event that the server rejects the deleteoperation, the user may be presented with a dialogue asking if he wishesto abandon the change. Doing so simply involves moving the _orig entryfor the deleted item back to the main table and deleting thecorresponding Deletelist entry. (Salesforce APIs used: REST DELETEquery.)

The resolveCreateConvert stage applies all locally-initiated create andconvertLead operations. These are stored in the Createlist FIFO. In theevent that the server rejects the create or convert operation, the usermay be presented with a dialogue asking if he wishes to abandon thechange. Alternately, if there is some data validation problem, the usermay instead edit a field in the failing object and reattempt theoperation. (Salesforce APIs used: REST POST query.)

The resolveThreeWayDiff stage does a three-way-diff between the main,_orig and _synced tables. Entries that have changed on the server getwritten locally and vice-versa. In the case that a field has changed onboth the client and server, the user is prompted to select a winner.Other server rejections of the transaction may result in the userabandoning or editing and retrying, as for the create case. (SalesforceAPIs used: REST PATCH query.)

The resolveMoveSyncedToMain stage moves the remaining _synced tableentries into their respective main tables.

At the end of a successful complete run of the sync algorithm, assumingthere has not been any additional work performed by the user while thesync is running, the SObject main tables will contain all of the objectinformation, and this information will be up to date with the server.All of the other tables in the SObject Table Group (_orig, _synced,_todelete, _tosync) will be empty, and the Createlist and Deletelistshared support tables will be empty.

Note that if the ServerWrittenThisSynclteration property is set at anypoint during the iteration, or the query/fetch stages pull new ormodified records from the server, the entire sync algorithm is repeated.This provides a converging effect to ensure that when the sync is donethe client and server are as up to date as possible.

Sync Algorithm (Typical)

FIG. 6 illustrates a typical operation of the sync algorithm and showsin more detail the interaction between the algorithm, some of the localtables, the Salesforce cloud, and the user (as described in the previoussection).

Offline Mode Local Transactions

One of the key properties of the SObject Table technique is that themain table may in some instances be made available to the applicationfor user interaction via various actions, some of which will bedescribed in greater detail below.

Create

FIG. 7 illustrates a create case where the application creates a uniquetmpld, which the application will use temporarily. The application maythen swap the tmpld with a real Id when the create operation is postedto the cloud. Then an entry in the SObject main table is created (withCuriumCreated=TRUE) and a Createlist entry is enqueued (withIsCreate=TRUE).

At sync time, the Createlist may be dequeued and the Salesforce REST APIPOST (create) may be called to get a real ID. This real ID needs to beswapped for the tmpld in all places, or at least a portion thereof.Finally, the ServerWrittenThisSynclteration property is set to indicatethat another iteration of the sync algorithm should take place. Thiswill fetch back the fully formed entry just created on the server sincethe newly created server-side object's LastModifiedDate will be laterthan the end window timestamp of the current sync iteration. We want theserver's full copy because some fields may be calculated and we don'twant to reengineer that work on the client side.

Abandoning a create action simply involves deleting the main table entryand deleting the associated Createlist entry.

Update

FIG. 8 illustrates an update case for the application. The first time anuntouched SObject row is updated, the application makes a copy of therow in the _orig table. This enables both unwinding of the update aswell as enabling the three-way-diff to determine which fields need to bewritten to the server. In addition, the CuriumUpdated field in the maintable object is set to TRUE, so we can now recognize this object asbeing dirty.

At sync time, the main table, _orig table, and _synced table arecompared for this object (correlated by Id). If there is no _syncedtable entry then this object has not been touched on the server sidesince the last sync, and the main table object is written to the server.If there is a _synced table entry, then the _orig table is compared todetermine whether the field was modified locally or on the server. Inthe case where both a local and a server modification was made to thesame field, the user may be prompted to settle a winner or choose a newvalue entirely. After doing this three-way compare, the appropriatefields are written to the server (with a Salesforce REST API PATCH(create) call) and the local copies of the object such that they are thesame. At this point, the _orig and _tosync table entries (if existing)are deleted and the CuriumUpdated value in the main table should be setto FALSE (since the value now tracks the server value).

Finally, the ServerWrittenThisSynclteration property is set to indicateanother iteration of the sync algorithm should take place. This willfetch back the fully formed entry just written on the server since theserver-side object's LastModifiedDate will be later than the end windowtimestamp of the current sync iteration. Abandoning an update justrequires moving the _orig entry back to the main table.

Delete

FIG. 9 illustrates the operation of a locally-initiated delete casewhere we move the main table entry into the _orig table and create aDeletelist entry. At sync time, the Deletelist is dequeued, and theSalesforce REST API DELETE method is called with the proper Id. Finally,the local _orig object is deleted. Abandoning a delete only requiresmoving the _orig entry back to the main table and dropping theDeletelist entry.

Convert

FIG. 10 illustrates the operation of a convertLead (or convert forshort) operation, which may be very similar to create in many respects,since the result of a convert can optionally create an OpportunitySObject record. The first step in a convert is marking the Lead objectin the main table with CuriumConverted=TRUE. Next, assuming the convertoperation is creating an opportunity, the Opportunity object is createdwith a tmpld and set with CuriumCreated=TRUE. Finally, a Createlist FIFOentry is enqueued with IsCreate=FALSE and the convertLead argumentsstored in the new Createlist row, along with the opportunity tmpld.

At sync time, the Createlist is dequeued (with an IsCreate=FALSE item)and the Salesforce SOAP API convertLead is called to get a real Id. Thisreal Id needs to be swapped for the tmpld in all places. Finally, theServerWrittenThisSynclteration property is set to indicate anotheriteration of the sync algorithm should take place. This will fetch backthe fully formed entry just created on the server since the newlycreated server-side object's LastModifiedDate will be later than the endwindow timestamp of the current sync iteration. We want the server'sfull copy because some fields may be calculated and we don't want toreengineer that work on the client side.

QueryWave

Referring now to FIG. 11, which illustrates a QueryWave technique forselecting and transferring objects from the Salesforce cloud server tothe client. In this instance, the client sends a series of SOQL request“waves” to the server, reading the data a chunk at a time. Each waverequest corresponds to one month's (or partial month's) worth ofcreated/modified records. Limiting the amount of data in any one chunkreduces the likelihood the server will timeout in failure trying tobuild an enormous query response. All SObjects may be queried inparallel for best performance.

OnlineIndicator

FIG. 12 illustrates an OnlineIndicator, which is a novel UI componentfor simultaneously showing the sync status, online/offline status, andthe number of local updates that need to be synced to the cloud server.The OnlineIndicator can also be pressed to bring up a short menu ofactions available to the user regarding syncing and online/offlinestate.

FIG. 13 illustrates an exemplary computing system 1300 that may be usedto implement an embodiment of the present technology. The system 1300 ofFIG. 13 may be implemented in the contexts of the likes of computingsystems, networks, servers, or combinations thereof. The computingsystem 1300 of FIG. 13 includes one or more processors 1310 and mainmemory 1320. Main memory 1320 stores, in part, instructions and data forexecution by processor 1310. Main memory 1320 may store the executablecode when in operation. The system 1300 of FIG. 13 further includes amass storage device 1330, portable storage medium drive(s) 1340, outputdevices 1350, user input devices 1360, a graphics display 1370, andperipheral device(s) 1380.

The components shown in FIG. 13 are depicted as being connected via asingle bus 1390. The components may be connected through one or moredata transport means. Processor unit 1310 and main memory 1320 may beconnected via a local microprocessor bus, and the mass storage device1330, peripheral device(s) 1380, portable storage device 1340, andgraphics display 1370 may be connected via one or more input/output(I/O) buses.

Mass storage device 1330, which may be implemented with a magnetic diskdrive or an optical disk drive, is a non-volatile storage device forstoring data and instructions for use by processor unit 1310. Massstorage device 1330 may store the system software for implementingembodiments of the present invention for purposes of loading thatsoftware into main memory 1320.

Portable storage medium drive(s) 1340 operates in conjunction with aportable non-volatile storage medium, such as a floppy disk, compactdisk, digital video disc, or USB storage device, to input and outputdata and code to and from the computer system 1300 of FIG. 13. Thesystem software for implementing embodiments of the present inventionmay be stored on such a portable medium and input to the computer system1300 via the portable storage medium drive(s) 1340.

Input devices 1360 provide a portion of a user interface. Input devices1360 may include an alphanumeric keypad, such as a keyboard, forinputting alpha-numeric and other information, or a pointing device,such as a mouse, a trackball, stylus, or cursor direction keys.Additionally, the system 1300 as shown in FIG. 13 includes outputdevices 1350. Suitable output devices include speakers, printers,network interfaces, and monitors.

Graphics display 1370 may include a liquid crystal display (LCD) orother suitable display device. Graphics display 1370 receives textualand graphical information, and processes the information for output tothe display device.

Peripheral device(s) 1380 may include any type of computer supportdevice to add additional functionality to the computer system.Peripheral device(s) 1380 may include a modem or a router.

The components provided in the computer system 1300 of FIG. 13 are thosetypically found in computer systems that may be suitable for use withembodiments of the present invention and are intended to represent abroad category of such computer components that are well known in theart. Thus, the computer system 1300 of FIG. 13 may be a personalcomputer, hand held computing system, telephone, mobile computingsystem, workstation, server, minicomputer, mainframe computer, or anyother computing system. The computer may also include different busconfigurations, networked platforms, multi-processor platforms, etc.Various operating systems may be used including Unix, Linux, Windows,Macintosh OS, Palm OS, Android, iPhone OS and other suitable operatingsystems.

It is noteworthy that any hardware platform suitable for performing theprocessing described herein is suitable for use with the technology.Computer-readable storage media refer to any medium or media thatparticipate in providing instructions to a central processing unit(CPU), a processor, a microcontroller, or the like. Such media may takeforms including, but not limited to, non-volatile and volatile mediasuch as optical or magnetic disks and dynamic memory, respectively.Common forms of computer-readable storage media include a floppy disk, aflexible disk, a hard disk, magnetic tape, any other magnetic storagemedium, a CD-ROM disk, digital video disk (DVD), any other opticalstorage medium, RAM, PROM, EPROM, a FLASHEPROM, any other memory chip orcartridge.

While various embodiments have been described above, it should beunderstood that they have been presented by way of example only, and notlimitation. The descriptions are not intended to limit the scope of thetechnology to the particular forms set forth herein. Thus, the breadthand scope of a preferred embodiment should not be limited by any of theabove-described exemplary embodiments. It should be understood that theabove description is illustrative and not restrictive. To the contrary,the present descriptions are intended to cover such alternatives,modifications, and equivalents as may be included within the spirit andscope of the technology as defined by the appended claims and otherwiseappreciated by one of ordinary skill in the art. The scope of thetechnology should, therefore, be determined not with reference to theabove description, but instead should be determined with reference tothe appended claims along with their full scope of equivalents.

What is claimed is:
 1. A method for requesting data from a customerrelationship management system by a mobile device, across a network, themethod comprising: an approach for querying table information (for agiven SObject) by issuing up to N+1 queries from the mobile client tothe customer relationship management system, whereby each successivequery from query 0 to query N for a given CRM table requests a fixedperiod of time's worth of history (for example one month), with the N+1query for said CRM table requesting any remaining history; the dataindependence of individual CRM tables, whereby queries for differenttables do not interfere with one another and may proceed and concludeindependently and concurrently; and leveraging physical networkingequipment such as but not limited to bridges, routers and switches tofacilitate communications for synchronization.
 2. A method fordisplaying, on a mobile device display, the local database state andlast sync state, the method comprising: a geometric shape, such as butnot limited to a circle, which may be filled in with a color; and theuse of three different fill colors to represent the differentpossibilities of i) the last sync having failed, ii) the device beingoffline, or iii) the device being online.
 3. The method defined in claim2, further including: using an absence of any numbers or symbols withinthe geometric shape to indicate the last sync succeeded and the lack ofany locally stored data that needs to be synced with the customerrelationship management system; the use of a symbol, such as but notlimited to, an exclamation point (‘!’), displayed within the geometricshape to indicate the last sync failed (note that said symbol helpscolor-blind users, who may not be able to determine by sight which ofthe different fill colors is present); the use of a number displayedwithin the geometric shape to indicate how many local database changesexist that need to be synced with the customer relationship managementsystem.
 4. The method defined in claim 2, further including: the use ofa symbol, such as but not limited to, a number sign to indicate a largenumber of changes for when the number is too large to fit within thegeometric shape.
 5. The method defined in claim 2, further including:the use of a symbol, such as but not limited to, a question mark toindicate some other type of error occurred.